EP0220146B1

EP0220146B1 - Improvements to valves for gas cylinders

Info

Publication number: EP0220146B1
Application number: EP86850338A
Authority: EP
Inventors: Erik T. Eriksson
Original assignee: AGA AB
Current assignee: AGA AB
Priority date: 1985-10-18
Filing date: 1986-10-08
Publication date: 1990-01-31
Anticipated expiration: 2006-10-08
Also published as: DK496286D0; SE8504907L; EP0220146A1; DE3668683D1; DK496286A; SE450160B; ATE50038T1; SE8504907D0

Abstract

The disclosure relates to an arrangement in a valve for high-pressure gas cylinders, primarily for oxygen gas cylinders, in order, during the opening phase, to prevent gas-rush through the valve, the valve comprising an inlet connection (1) intended to be screwed into the gas cylinder and including an inlet passage (3) for the gas. A tubular sleeve member (6) is disposed in the gas passage and is axially movable along a predetermined distance. When the valve is closed, the one end of the sleeve member (6) abuts against the movable sealing member (5) of the valve, and its other end abuts against spring means (10) disposed in the gas passage. The sleeve member (6) is of such diameter that a gap (16) is obtained between the sleeve and the gas passage wall, the sleeve (6), in the initial phase of the opening movement of the valve, abutting against the movable sealing member (5) along the above-mentioned distance, such that a slight volume of gas flows through the gap, and, on further opening movement, the movable sealing member departs from the sleeve (6) and full gas flow is obtained through the valve.

Description

A lift valve for high-pressure gas cylinders, primarily fdr oxygen gas cylinders, the valve comprising an inlet connection intended to be screwed into the gas cylinder, a valve seat between inlet and outlet passages, a movable sealing member, the valve further including an arrangment to prevent, during the opening phase, gas-rush through the valve, said arrangement comprising a tubular member disposed in the gas passage and axially movable with respect to the sealing member and urged against the member by spring means, said tubular member being arranged to provide a gap with the sealing member when moved a predetermined distance, so to allow a small gas flow through the valve during the initial phase of the opening movement.
It is previously known in this art that if a valve connection to a gas cylinder containing oxygen gas or oxygenenriched gas at high pressure is quickly opened - or "snatched open" - ignition may occur in the valve or in the equipment connected to the valve, for example a regulator. In such an event, not only may the component in question be destroyed, but such an ignition may also entail damage to other parts in the gas distribution system. In order that such ignition can take place, it is necessary that three elements be present, namely oxidation agent, fuel and ignition energy. Here, the oxygen is the oxidation agent and the valve material is the fuel. The ignition energy consists of the compression heat generated when the gas is compressed from low to high pressure. In the present case, when high-pressure oxygen is released into the valve chamber and rapidly compresses the residual oxygen in the chamber, a violent increase of the temperature of the gas will be obtained. This temperature increase may exceed the threshold ignition temperature of the material. If, for example, in a valve, oxygen is rapidly compressed from 1 bar and 20_°C to 200 bar, the ultimate temperature of the gas will be of the order of magnitude of approx. 1200_°C. In a valve which is made of brass and which may also contain components of other materials, ignition may take place in the event of such a rapid compression, with consequential temperature increase. In the German publication DE-A 2 429 071 is disclosed a valve of a high-pressure gas cylinder comprising an arrangement to prevent a gas rush through the valve during the initial phase of the opening movement of the valve. In the disclosed valve a part of the valve spindle is designed to surround a part of the valve cone. This part of the cone is axially movable in the spindle. The cone is urged against the spindle by spring means.
In the cone is arranged a central axial through hole.
From this hole is arranged a radial hole to the outer surface of the cone. The orifice of the radial hole is covered by the spindle when the valve is closed. In the initial phase of the valve opening movement said orifice will be set free, so that a small volume of gas will flow from the inlet to the outlet of the valve. During a further turning of the valve knob the cone will leave the valve seat and the valve will be fully opened. However, an arrangement according to the German document requires a special design of the cone and the spindle which can be complicated to achieve. A valve including this arrangement will therefore be difficult and expensive to manufature.
The object of the present invention is to realise an improvement of the arrangement in the valve which prevents gasrush rush through the valve and, as a result, the rapid compression of the gas. The present invention is, here, essentially characterised in that a tubular member is a tubular sleeve arranged in the gas passage between the valve seat and the inlet of the valve, the one end of said sleeve abutting, when the valve is closed, against the movable sealing member of the valve, and the other end of said sleeve abutting against a spring member, said sleeve being of such a diameter that a gap is obtained between the outer surface of the sleeve and the gas passage wall, the end of said sleeve facing said spring member is provided with a flange member which, when the valve is open, is disposed to abut against a first recess in the gas passage, and which is provided with at least one aperture allowing continuous gas flow from the valve inlet to the gap, the sleeve, in the initial phase of the opening movement of the valve over said predetermined distance, abutting against the movable sealing member such that a slight volume of gas flows through the gap to the valve outlet and, on further opening movement, the movable sealing member departs from the sleeve and maximum gas flow is obtained through the valve. The invention is further characterised in that the gap width and gap length are dimensioned such that, in the above-mentioned initial phase, the rising time of the gas flow to maximum flow is of such duration that the gas compressed in the valve housing during the rising time of the gas flow will attain a temperature which is lower than the threshold ignition temperature of the valve material.

BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

The nature of the present invention and its aspects will be more readily understood from the following brief description of the accompanying Drawings, and discussion relating thereto.
In the accompanying Drawings:

Fig. 1 is a longitudinal section through a conventional gas cylinder valve;
Fig. 2 is a cross-section through the inlet connection and component parts inserted therein; and
Fig. 3 illustrates graphically the gas flow through the valve, on the one hand for a conventional valve, and, on the other hand, for a valve fitted with the arrangement according to the present invention.

DESCRIPTION OF PREFERRED EMBODIMENT

Referring to the Drawings, Fig. 1 shows a cylinder valve. This comprises an inlet connection 1 intended to be screwed into a gas cylinder, and an outlet connection 2 intended for connection to an outlet conduit. Gas from the cylinder passes through the gas passage 3 and, if the valve is open, past the valve seat 4 and out through the channel in the outlet connection 2. The valve is closed by turning the valve knob, in which event the movable sealing member 5 is, by means of the operating mechanism of the valve (in the illustrated embodiment a spindle and ball), urged against the seat 4 and thereby closes the gas passage 3. When the valve is opened, the movable sealing member 5 is, thus, lifted from the valve seat 4.
Fig. 2 illustrates the outlet connection 1 and the lower portion of the movable sealing member 5 when the valve is opened and when the valve is closed, in each half of the Drawing, respectively. Bores 14 and 15 are provided in the gas passage 3 in the outlet connection. A sleeve-shaped member 6 is disposed in the gas passage most proximal the valve seat 4. This member is provided with a flange 7 at its end facing away from the valve seat. The flange is provided with one or more apertures 9. A spring 10 is disposed in the bore 15 in the gas passage, the flange 7 abutting against the upper end of the spring. The opposite end of the spring 10 abuts against a backing washer 11 which is disposed in the bore 14. In the illustrated embodiment, the washer 11 is held in place by a locking washer 13. However, it is also conceivable without departing from the spirit and scope of the present invention to thread the backing washer in place in the bore.
The sleeve 6 is disposed to be axially movable in the gas passage. Moreover, the sleeve 6 is of such diameter that a gap 16 is formed between the sleeve and the gas passage wall. However, movement towards the valve seat is restricted by the end surface 8 of the bore 15. When the valve is closed (the right-hand half of Fig. 2), the end surface of the sleeve 6 will, because of the action of the spring 10, abut against the movable sealing member 5, in which case no gas can pass from the gas passage into the valve housing. When the valve is opened by turning the valve knob, the movable sealing member 5 will move away from the seat 4. However, the end surface of the sleeve 6 is held urged against the movable sealing member by the action of the spring 10. The sleeve 6 will abut against the sealing member a distance which corresponds to the travel of the flange 7 to the end surface stop 8 in the gas passage. Once the movement of the sleeve has been arrested, the sealing member 5 is released and the valve is fully open (the left-hand half of Fig. 2).
During the time the sleeve 6 abuts against the sealing member 5, gas will now flow from the gas passage through the apertures 9 in the flange 7 into the gap 16 between the sleeve wall and the wall of the gas passage. Because the valve seat 4 is somewhat chamfered, viewed from the centre, a gap will be created between the seat and sealing member through which gap the gas flows out into the valve housing. During the first phase of the opening movement of the valve, there will hereby be obtained a gas flow solely through the above-described gaps. Not until the sealing member 5 has departed from the end surface of the sleeve 6 will maximum flow be obtained through the valve.
The gap between the sleeve 6 and the wall of the gas passage has been given a specific width and length, since the gas flow rate through the gap is determined by these magnitudes. The gap width and gap length are, here, dimensioned such that, during the initial phase of the opening movement of the valve, a rising time for the gas flow from zero to maximum flow is obtained which is of such duration that no "quick" compression of the gas enclosed in the valve housing will be occasioned. The ultimate temperature which the gas attains as a result of this arrangement is considerably lower than the lowest threshold ignition temperature of the valve material. Fig. 3 illustrates the rising time for the gas flow, first for a conventional valve (the upper diagram (a)), and secondly for a valve provided with the novel arrangement according to the present invention (the lower diagram (b)). As will be apparent from these diagrams, the rising time for a conventional valve is approx. 50 msec. and for a valve fitted with the novel arrangement approx. 300 msec. Hence, by the present invention it has become possible to increase the rising time by a factor of approx. 6. In order to obtain a rising time which does not give rapid, and thereby dangerous, compression, the gap width should lie in the range of from 50 to 150 µ, and the gap length in the range of from 5 to 15 mm. In the curve illustrated in Fig. 3, a gap width of 80 and a gap length of 10 mm were employed.
Thus, be means of the novel arrangement disclosed in the foregoing, it has become possible to avoid the rapid compression, and consequential temperature increase of the gas in the valve housing, whereby the risk of ignition has been obviated. By means of the novel arrangement as herein disclosed, there will always be obtained, during the initial phase of the opening movement of the valve, a constant rising time for the gas flow irrespective of the speed with which the valve knob is turned. As. a further result of the novel arrangement as herein disclosed, this constant rising time will also be obtained irrespective of the operating mechanism disposed in the valve between the knob and the movable sealing member, thus irrespective of whether the valve comprises spindle and ball, diaphragm or bellows-type arrangement.

Claims

1. A lift valve for high-pressure gas cylinders, primarily for oxygen gas cylinders, the valve comprising an inlet connection (1) intended to be screwed into the gas cylinder, a valve seat (4) between inlet and outlet passages (3, 2), a movable sealing member (5), said valve further including an arrangement to prevent, during the opening phase, gas-rush through the valve, said arrangement comprising a tubular member (6) disposed in the gas passage and axially movable with respect to the sealing member (5) and urged against the member by spring means (10), said tubular member (6) being arranged to provide a gap with the sealing member (5) when moved a predetermined distance, so to allow a small gas flow through the valve during the initial phase of the opening movement, characterised in that said tubular member (6) is a tubular sleeve (6) arranged in the gas passage between the valve seat (4) and the inlet (3) of the valve, the one end of said sleeve abutting, when the valve is closed, against the movable sealing member (5) of the valve, and the other end of said sleeve abutting against a spring member (10), said sleeve being of such a diameter that a gap (16) is obtained between the outer surface of the sleeve and the gas passage wall, the end of said sleeve (6) facing said spring member (10) is provided with a flange member (7) which, when the valve is open, is disposed to abut against a first recess (8) in the gas passage, and which is provided with at least one aperture (9) allowing continuous gas flow from the valve inlet (3) to the gap (16), the sleeve (6), in the initial phase of the opening movement of the valve over said predetermined distance, abutting against the movable sealing member (5) such that a slight volume of gas flows through the gap (16) to the valve outlet (2) and, on further opening movement, the movable sealing member (5) departs from the sleeve (6) and maximum gas flow is obtained through the valve.

2. The valve as claimed in claim 1, characterised in that gap width and gap length are dimensioned such that, in said initial phase, the rising time of the gas flow to maximum flow is of such duration that the gas compressed in the valve housing during the rising time will attain a temperature which is lower than the lowest threshold ignition temperature of the valve material.

3. The arrangement as claimed in claim 3, characterised in that the gap width lies in the range of from 50 to 150µ and the gap length in the range of from 5 to 15 mm.

4. The arrangement as claimed in claim 3, characterised in that the gap width is preferably 80 µ and the gap length preferably 10 mm.